Implantable micro-sensor to quantify dissolved inert gas

ABSTRACT

Methods and devices including implantable micro-sensors used to detect tissue-dissolved inert gas and to detect microbubble formation to avoid Caisson disease are described. The disclosed methods and devices are based on measuring the refractive index changes in hydrophobic liquids after absorbing an inert gas such as nitrogen. The changes in the refractive index are based on implementing one of an interferometry, optical microcavity resonance shift, a photonic crystal resonance, a beam deflection, a resonance tuning or detuning, an amplitude change, or an intensity change method.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of U.S. Non-Provisional application Ser. No. 16/719,371 filed on Dec. 18, 2019, which claims priority to U.S. Provisional Application 62/790,151 filed on Jan. 9, 2019, the contents of both of which are incorporated herein by reference in their entirety.

FIELD

The presented disclosure is related to micro-sensors, in particular implantable micro-sensors to quantify dissolved inert gas, and more particularly to implantable micro-sensors used to detect tissue-dissolved nitrogen and to detect microbubble formation to avoid e.g. Caisson disease.

BACKGROUND

Throughout this document the term “tissue-dissolved” will refer to “dissolved in tissue”, with particular reference to the biological tissue of the diver.

Caisson disease (known also as “the bends”) is a potentially lethal health risk for divers breathing a nitrogen gas mixture. As pressure increases with depth, nitrogen dissolves in the tissues of the diver. When the diver ascends, the positive pressure difference stimulates bubble formation in the tissues and blood vessels, potentially causing serious tissue damage, embolism, and possibly death. Generally, the reason for breathing mixtures to contain an inert gas is because pure oxygen is toxic as it is highly reactive and will burn tissues. In the atmosphere, oxygen is diluted by nitrogen, therefore human lungs can withstand it. A diver generally requires a similar setup. For simple shallow dives, divers usually use compressed air, which is inexpensive and already comes at the necessary ratio between oxygen and an inert gas. For deeper dives, divers use more complex mixtures of other inert gasses, e.g. helium. However, any inert gas that does not have its own biological system of efficient transport through the blood (as oxygen and carbon dioxide have through hemoglobin binding) will produce the same or similar decompression problem.

To help avoid these risks, divers time the ascent in accordance with diving charts, to allow for the excess nitrogen to be exhaled safely. However, the charts are only approximate, while biological variability and the relative randomness of bubble formation produce significant uncertainty. Moreover, slow ascent might be impracticable in cold environments, hostile waters, or clandestine missions. Slow ascent might also be undesirable in emergencies.

SUMMARY

The teachings of the present disclosure address the problems described in the previous section and provide methods to measure the concentration of nitrogen dissolved in tissues and monitor microbubble formation. The described methods and devices may also use the output of that measurement in combination with diving charts and depth information to form a “diving solution” recommendation to the diver in real time using a handheld/wearable monitor.

The property of nitrogen and other inert gases to preferentially absorb into hydrophobic environments is known to the person skilled in the art. This property is known as part of the current understanding of the mechanism of nitrogen narcosis, where nitrogen dissolves in the cell membranes, which are made of a double layer of lipids. The disclosed devices and methods use such property to build implantable sensors.

Further aspects of the disclosure are provided in the description, drawings and claims of the present application.

According to a first aspect of the present disclosure, a sensor is provided, comprising: a micro-chamber capsule filled with a hydrophobic liquid; and a measurement unit connected with the micro-chamber capsule; wherein the measurement unit is configured to: detect and quantify a concentration of an inert gas by measuring a physical change of the hydrophobic liquid due to a dissolving of the inert gas in the hydrophobic liquid; and generate measured results.

According to a second aspect of the present disclosure, a method of detecting and quantifying a concentration of an inert gas dissolved in a hydrophobic liquid is disclosed, providing: measuring a physical change of the hydrophobic liquid due to the dissolving of the inert gas in the hydrophobic liquid; and providing measured results including the concentration of the inert gas.

According to a third aspect of the present disclosure, a method of detecting and quantifying microbubble formation of an inert gas dissolved in a hydrophobic liquid, comprising: measuring a physical change of the hydrophobic liquid due to the dissolving of the inert gas in the hydrophobic liquid; and providing measured results including the concentration of the inert gas.

DESCRIPTION OF THE DRAWINGS

FIG. 1 shows an electronic system according an exemplary embodiment of the present disclosure.

FIG. 2A shows a flowchart illustrating methods according to the teachings of the present disclosure

FIG. 2B shows examples of physical changes in a hydrophobic liquid after absorbing an inert gas such as nitrogen.

DETAILED DESCRIPTION

FIG. 1 shows an electronic system (100) comprising a sensor (110) and a wearable monitor (120) in accordance with an embodiment of the present disclosure. The implantable sensor (110) comprises a micro-chamber capsule (111). Throughout this document the term “capsule” will mean “enclosed chamber”. In accordance with a further embodiment of the present disclosure, the measured data may be transmitted wirelessly from the measurement unit (112) to the wearable monitor (120), as shown by the arrow (130). The wearable monitor (120) may provide power to the implantable sensor (110) as shown by the arrow (140). Dimensions of the micro-chamber capsule may be on the scale of microns, tens of microns or hundreds of microns. As also shown in FIG. 1, the sensor (110) may optionally be implemented on a microchip (113)

In accordance with the teachings of the present disclosure, the micro-chamber (111) may be filled by a hydrophobic liquid such as lipid, gel, or oil. Physical properties of the hydrophobic liquid may change due to absorption of an inert gas such as nitrogen, helium, neon, krypton, argon, or a mixture thereof. The change of such physical properties is then detected and measured by measurement unit (112) by using for example electronic or interferometric techniques. Moreover, the change in physical properties of the liquid due to the absorption of the gas (e.g. nitrogen) can then be calibrated within the measurement unit and with known nitrogen concentration. In what follows, the disclosed concept will be described more in detail and through some exemplary embodiments.

As an example, absorption of nitrogen would change the refractive index of the working liquid. In an exemplary embodiment, interferometric techniques may be used to detect and measure the changes in the refractive index. These techniques have been shown to be miniaturizable, particularly with the use of photonic crystals, Bloch arrays, and the use of optical micro-cavities etc. In accordance with further embodiments of the present disclosure, to help miniaturization, the actual detection may be set up to be looking for a tuning or detuning shift of preset magnitude. Other embodiments in accordance with the present disclosure may be envisaged where an array of sensors such as the implantable sensor (110) of FIG. 1 are implemented in a microchip where an overall calibration may be performed by varying the shift across the array. The change in the refractive index may be measured using various techniques such as interferometry, Optical microcavity resonance shift, photonic crystal resonance, beam deflection, resonance tuning or detuning, amplitude change, or intensity change.

In an alternative embodiment in accordance with the present disclosure, the measurement unit (112) comprises micro-fabricated and micro-patterned electrodes to measure the electrical capacitance or conductivity in the micro-chamber capsule (111) to detect the absorbed gas (e.g. nitrogen). Using micro-fabricated and micro-patterned electrodes improves the sensitivity of measurements. Absorption of nitrogen would provide additional diatomic molecules to the liquid (acting as a dielectric) within the micro-chamber capsule (111), additional diatomic molecules being subject to dielectric polarization when an electric field is applied. The change in dielectric constant can then be measured by the measurement unit (112). This effect can be amplified by adding metallic particles to the micro-chamber material. As the hydrophobic material is compressed or expands with the introduction of inert gas, the metallic particles change the conductivity of the metal/polymer composite, and change the measured capacitance or conductivity that is measured.

According to embodiments of the present disclosure, the measurement unit (112) may be made based on optical measurements of turbidity to detect the onset of microbubble formation. In the absence of bubbles, the liquid (e.g. lipid or oil) inside the micro-capsule (111) is optically clear. When microbubbles start forming, they would act as optical scatterers increasing the apparent turbidity of the liquid. Alternatively, the optical measurement may be based on a reflection, which will turn from specular to diffusive when the microbubbles start forming. Both techniques may be implemented based on an intensity measurement, which is known to be easily miniaturizable. Other embodiments in accordance with the present disclosure may also be made wherein the microbubble formation is detected by measuring the electrical conductivity and/or capacitance of the liquid inside the micro-chamber capsule (111). In such a case, the measurement unit (112) comprises, preferably, micro-fabricated and micro-patterned electrodes. The formation of the bubbles will displace the dielectric liquid away from the electrodes, thereby lowering capacitance and/or conductivity of the system, depending on what liquid is used.

FIG. 2A shows a general flowchart (200) illustrating the disclosed methods where first a physical change due to absorption of a gas in a liquid is detected and measured, and the measured results are then transmitted to a wearable device. Examples of such physical changes are summarized in FIG. 2B. Various exemplary electrical and optical techniques that can be used to measure such changes were described in the previous paragraphs.

Referring back to FIG. 1, the electronic system (100) can be used to improve safety and efficiency of diving operations. During a diving operation, the wearable monitor (120) may be worn by the diver, and the implantable sensor (110) is implanted or injected in the diver's body. As an example, a small incision can be made in the skin and the microchip is inserted in the incision under the skin. The incision is sufficiently small such that the skin can just be glued closed (no stitches required). Alternatively, the device can be miniaturized to fit through an injection needle, and inserted into the subdermal space underneath the reader. The recovery is very quick (full heal within a week) due to the small size of the incision. The wearable monitor (120) communicates wirelessly with the implantable sensor (110) to provide diver with the measured results. According to various embodiments of the present disclosure:

Power is supplied to the implantable sensor (110) by the wearable monitor (120) through electromagnetic induction.

The implantable sensor (110) is fabricated on a micro-chip.

The wearable monitor (120) may use the received measured results from the implantable sensor (110) to provide visual or sonic feedback to the diver or the user wearing the wearable monitor (120).

The wearable monitor (120) may be a handheld device.

The wearable monitor can be part of a health-monitoring system that includes other sensors and provides integrated output to external monitoring systems. The wearable monitor may be connected to that system wirelessly or by wire as part of a wearable biomedical suit.

Measuring the nitrogen concentration e.g. by the measurement unit seeing a shift in the absorption maximum may be independent of using turbidity to measure microbubble formation. The nitrogen concentration can be converted into partial pressure and com-pared to the ambient pressure to produce a risk assessment of bubble formation, with its own three zones defined (green, yellow, red). Low risk may be represented as “green status”. Higher risk may be represented as “yellow” or “red” to the diver.

The microbubble turbidity measurement can independently indicate if bubbles are formed or not. That is a “yes/no” measurement in general, but some calibration may be performed to graduate it into zones if desired, e.g. based on the quantification of the measured turbidity and some calibration to the severity of microbubble formation.

Both measurement (inert gas concentration) and bubble turbidity may be implemented on the same chip with both outputs transmitted to the wearable device to display.

The measured data may be combined with preprogrammed diving charts and measured depth to calculate the best plan for ascent and change it dynamically as new data is received in real time. Further biometrics may also be tied in.

The measured data may be calibrated offline without involvement of the diver and then used in real time. This is performed by applying a known ambient pressure and concentration of the inert gas (e.g. nitrogen), then waiting for equilibration followed by performing titrated measurements to be used to calibrate the measured data. 

1.-23. (canceled)
 24. A sensor comprising: a capsule filled with a hydrophobic liquid; and a measurement unit connected with the capsule, the measurement unit being configured to detect and quantify a concentration of an inert gas by measuring a physical change of the hydrophobic liquid due to a dissolving of the inert gas in the hydrophobic liquid, the physical change being a change in a refractive index of the hydrophobic liquid, wherein the measurement unit is further configured to measure the change in the refractive index by implementing one of an interferometry, optical microcavity resonance shift, a photonic crystal resonance, a beam deflection, a resonance tuning or detuning, an amplitude change, or an intensity change method.
 25. The sensor of claim 24, wherein the hydrophobic liquid comprises one of lipid, gel, or oil.
 26. The sensor of claim 24, wherein the inert gas comprises one of nitrogen, helium, neon, krypton, argon, or a mixture thereof.
 27. The sensor of claim 26, wherein dimensions of the capsule are on a scale of microns, tens of microns, or hundreds of microns.
 28. The sensor of claim 27, wherein the sensor is implantable in animal or human subjects
 29. A method of detecting and quantifying a concentration of an inert gas dissolved in a hydrophobic liquid, comprising: applying the inert gas with a known ambient pressure and a known concentration to the hydrophobic liquid, the hydrophobic liquid comprising one or lipid, gel or oil; waiting for equilibration; taking titrated measurements of a physical change of the hydrophobic liquid due to the dissolving of the inert gas in the hydrophobic liquid, thereby calibrating the measured results in real time; and providing measured results including the concentration of the inert gas.
 30. The method of claim 29, further comprising wirelessly transmitting the measured results to a wearable monitor; and displaying the measured results by the wearable monitor.
 31. The method of claim 30, further comprising: filling a micro-chamber placed in a micro-chip with the inert gas; implementing the measuring on the micro-chip; implanting the micro-chip in a body of a diver wearing the variable monitor; and combining the measured results with a pre-programmed diving chart saved in the wearable monitor to generate a diving plan for the diver.
 32. A sensor comprising: a capsule filled with a hydrophobic liquid; and a measurement unit, connected with the capsule, comprising micro-patterned electrodes configured to detect and quantify an absorbed inert gas by measuring a change in a dielectric constant of the hydrophobic liquid.
 33. The sensor of claim 32, wherein the hydrophobic liquid contains metal particles.
 34. The sensor of claim 33, wherein dielectric constant changes of the hydrophobic liquid containing metal particles as a function of absorbed inert gas are measured when an electric field is applied across the hydrophobic liquid containing metal particles.
 35. The sensor of claim 32, wherein the micro-patterned electrodes configured to detect and quantify an absorbed inert gas by measuring a conductivity of the hydrophobic liquid.
 36. The sensor of claim 32, wherein the micro-patterned electrodes configured to detect and quantify an absorbed inert gas by measuring real and imaginary components to an impedance across the micro-patterned electrodes.
 37. The sensor of claim 32, wherein the imaginary component of the impedance across the micro-patterned electrodes is a capacitance.
 38. The sensor of claim 32, wherein detection of the absorbed inert gas provides additional diatomic molecules to change the dielectric constant of the hydrophobic liquid.
 39. The sensor of claim 32, wherein the measurement unit is further selected from the group consisting of an interferometry measurement unit, an optical microcavity resonance measurement unit, a photonic crystal resonance measurement unit, a beam deflector measurement unit, a resonance tuning or detuning measurement unit, an amplitude change measurement unit, and an intensity change measurement unit. 